DE1143858B - Multi-level electronic number chain - Google Patents

Description

Multi-stage electronic counting chain The invention relates to a multi-stage electronic counting chain with a plurality of interconnected bistable circuits, which depending on input pulses in sequence of their one switching state can be switched to the other switching state and two cross-linked Contain transistors, one of which is blocked in each of the two switching states and one is in charge.

The previously known counting chains of the aforementioned type are very complex and elaborately designed. So - be with a previously known Embodiment-very complicated intermediate coupling circuits required each several electron tubes and a large number of resistors and capacitors contain. If one uses the electron tube functions in such a previously known circuit replaced by transistors according to known rules of electronics, results itself a circuit that is by no means simpler, but due to a use of even more components are more susceptible to failure.

The aim of the present invention is therefore that indicated in the introduction multi-level electronic counting chain with a minimum number of electrical ones To represent switching elements.

To solve the aforementioned problem, it is proposed according to the invention that the input electrodes in the aforementioned multi-stage electronic counting chain of the transistors of all bistable circuits in each case via impedances to the corresponding To couple parallel paths, which with the exception of the parallel path for the first bistable circuit of the chain can be made conductive when the opposite transistor of the preceding bistable circuit conducts, while the parallel path or paths for the transistors of the first circle of the chain are made conductive when the similar transistor of the last bistable circuit of the chain conducts, so that with the exception of the first bistable circle, all bistable circles in the chain of Are brought into a switching state one after the other by the individual input pulses, which corresponds to that of the previous bistable circuit, the first bistable Circle of the chain is brought into a switching state which corresponds to that of the last bistable Circle of the chain is opposite, so that the counting of the counting chain for one complete switching cycle is twice as large as the number of bistable circuits the chain.

In that, according to the invention, in each individual bistable circuit both switching states are used within the entire switching cycle, results the desired large savings in electrical and electronic components and also a significantly higher working speed, as there are no delay times for resetting or preparing bistable circuits Circles occur.

In the case of the coupling impedances used according to the invention, it can be are ohmic resistors. In this context it is then also possible according to a further feature of the invention to modify the counting chain according to the invention so that that the parallel paths coupled to the input electrodes of the transistors of a the bistable circle not in the first position in the chain are the output paths contain further transistors whose input electrodes match the output electrodes the corresponding transistors of the preceding bistable circuit are coupled, so that these further transistors are non-conductive when the transistors of the preceding bistable circuit are conductive and vice versa, and that those with the Input electrodes of the transistors coupled parallel paths of the first bistable Circle of the chain contain the output current paths of other transistors whose Input electrodes with the output electrodes of the opposite transistors of the last bistable circuit of the chain are coupled, so that these further transistors become non-conductive when the transistors of the last bistable Circle are leading; and vice versa.

The invention is selected as an example below on the basis of Counting chains shown in the circuit diagrams of the drawings in more detail described. In the drawings: Fig. 1 shows two successive stages of one Embodiment of a counting chain, FIG. 2 shows the first and last stage of the counting chain FIGS. 1 and 3 show two successive stages of another embodiment a counting chain.

In the chains shown, the stages are connected in cascade bistable trigger circuits are formed, each of which is a pair of PNP-switched junction transistors Contains TR1 and TR2 with cross-connected bases and collectors. Although the Step or trigger pulses can be fed to all stages of the chain together, it is preferable to provide two step pulse lines S1 and S2 through which the Step pulses are alternately directed in this way; the first mentioned line the step pulses the odd numbered steps of the chain and the second-named line feeds the step impulses to the even-numbered stages. For example, from the Fig. 1 can be seen that each of the two transistors in stage n of the two shown Stages is provided with an input terminal, which from the base of the relevant Transistor leads to the step pulse line S1, where n is considered here as an odd number shall be. The input lines of the stages n -I- 1 are accordingly with the Step pulse line S2 connected. There is also one for each transistor of the stages Output line provided, which for example in the transistor TR1 stage n of Fig. 1 is connected to the collector of the transistor and a capacitor C in series with a diode D1, which is connected so that about negative pulses can be emitted at the output terminal. But that's where it is preferable to provide a further parallel path to the ground, in which a Diode D2 is connected so that they divert the positive pulses can.

The interstage coupling shown in FIG. 1 consists of a parallel path with variable impedance which is connected to each of the two input connections of the second of the two coupled stages. One of the two transistors in the first of the two stages serves as the variable impedance of the parallel path. More precisely, the parallel path always leads to the collector of the transistor to which the mentioned input connection is not assigned, ie the parallel path P1 for the input connection of the transistor TR1 in the stage n -f-1 leads to the collector of the transistor TR2 in the stage n, and the parallel path P2 for the input terminal of the transistor TR2 in the stage n -I- 1 leads to the collector of the transistor TR1 in the stage. In particular, depending on the shape of the step switching pulses supplied, given circuit constants it may be necessary to switch a further diode into the parallel path in such a way that it is forward-biased for negative pulses; when the collector end of the path is at about zero potential.

If the stage n is initially in the so-called normal state, in which the transistor TR1 is non-conductive and the transistor TR2 is highly conductive, and if the stage has just responded to a stepping pulse over the line S1 to switch to the other switching state, in which If the transistor TR1 becomes conductive and the transistor TR2 becomes non-conductive, the next step switching pulse arrives via the line S2 and is thus available for stage n + 1. If the transistor TR1 is conductive in stage n, however, this stepping pulse is derived from the input terminal of the transistor TR2 via the parallel path P2, so that the stepping pulse is fed to the stage n -I- 1 only via the input terminal of the transistor TR1. In this way, there is a switchover in the same direction in this stage, ie a switchover from the normal state to the other, so-called switched state. Every change in the switching state in this direction is accompanied by a negative output pulse via the diode D1, which is assigned to the transistor TR2 of the stage in which the switching state change occurs.

If, by continuing these switching state changes in the chain, the last stage N shown in FIG. 2 is brought into the switched state in which the transistor TR 1 is conductive, a reversing coupling RC is established between the collector of the transistor TR1 of the stage N and the input connection. of the transistor TR1 of the first stage 1 is effective in order to derive the next step switching pulse via the line S1, so that the step pulse is fed to the stage 1 only via the input terminal of the transistor TR2. Since the first stage 1 is in the switched state at this point in time, the stepping pulse at the base of the transistor TR1 causes this stage to be switched back to its normal state, in which the transistor TR 1 is non-conductive and the transistor TR2 is conductive, which then the reset is started by successive switchovers in the opposite direction. These switching state changes in the opposite direction are accompanied by output signals at the collectors of the transistors TR1, so that after all stages have been reset, the chain has completed a cycle in which output signals are initially output via the group of output connections of the transistors TR2 and then output signals via the return circuit Group of output terminals of the transistors TR1 are output. Since the switching coupling only ensures switching of the last stage N from the normal state to the switched state and not in the opposite direction, a special precaution is required at this connection point in order to initiate a new operating cycle. This special precaution can be a control with a synchronizing pulse, which ensures that the step pulses are derived from the input terminal of the transistor TR2 of the first stage 1 or that in some other way the stepping pulses only reach this stage via the input terminal of the transistor TR1. Deviating from the arrangement shown, the reversing coupling can also ensure switching state changes of the last stage N in both directions by providing a parallel path between the collector of the transistor TR2 of the last stage N and the input terminal of the transistor TR2 of the first stage 1 . The embodiment of the counting chain of Figure 3 differs from that already described in that the switching element with variable impedance in each of the parallel paths P1 and P2 is an additional transistor TR3 or TR4, of which the bases are connected to the collector of that transistor of stage n which corresponds to the transistor of stage n -I- 1 connected to the particular input terminal. In this sense, the base of the transistor TR3 in the path P1 is connected to the transistor TR 1 of the stages and of the transistor TR4 in the path P2 the base is connected to the transistor TR2 of the stage n . When the transistor TR1 of stage n becomes conductive by applying a stepping pulse to its base, the negative quiescent current is removed from the base of the transistor TR3 in order to make this transistor non-conductive. However, since the transistor TR2 of the stage n becomes non-conductive, such a negative quiescent current appears at the base of the transistor TR4 in order to make this transistor conductive. As a result, the stepping pulses in stage n -1-1 can only be applied to the same input terminal at which they were last applied to the preceding stage n.

In a manner similar to the arrangement according to FIG. 2, the Reversing coupling between the first and the last stage of the chain, however is not shown, differ from the interstage couplings in that the base of transistor TR3 to the collector of transistor TR2 the last Stage is connected and, if a path equivalent to path P2 is provided, in that the base of the transistor TR4 to the collector of the transistor TR1 connected to the last stage.

Although the above description in connection with transistors was done in PNP circuit, transistors can understandably also in NPN circuit be used by looking at the polarities of the supply voltages in per se Way changes.

It should also be noted that the preferred supply of the stepping pulses via two separate step switching lines only as an explanation of the more general one Principle is to be evaluated, the stepping pulses in such a grouping of the To distribute chain stages so that successive pulses also successive Stages are fed. The restriction of the switching options of a stage in a special group with the help of the interstage and reversing couplings no influence as long as the stepping pulses are fed to the other groups, so that the interstage and reversing couplings also extend between stages can, which do not necessarily follow one another, provided that the distance between the steps is not greater than the distance between the following of the two levels and the next preceding level of the same group.

Claims (3)

PATENT CLAIMS: 1. Multi-stage electronic counting chain with a plurality of interconnected bistable circuits, which are sequentially switched from one switching state to the other depending on input pulses and each contain two cross-connected transistors, one of which is blocked in the two switching states and one is conductive, characterized in that the input electrodes of the transistors (TR1, TR2, stage n + 1) of all bistable circuits are each coupled via impedances to corresponding parallel paths (P1, P2) which, with the exception of the parallel path (RC) for the first bistable circuit of the chain can be made conductive when the opposite transistor (TR2, TR1, stage n) of the preceding bistable circuit is conductive, while the parallel path or paths for the transistors of the first circuit of the chain are made conductive when the similar transistor of the last bistable Circle of the chain conducts, so that with the exception of the first bistable circuit all bistable circuits of the chain are sequentially brought into a switching state by the individual input pulses, which corresponds to that of the preceding bistable circuit, and that the first bistable circuit of the chain is in a switching state which is opposite to that of the last bistable circuit of the chain, so that the count of the counting chain for a complete switching cycle is twice as large as the number of bistable circuits in the chain. 2. Counting chain according to claim 1, characterized in that the impedances are ohmic resistances are. 3. Counting chain according to claim 2, characterized by such a modification, that the parallel paths coupled to the input electrodes of the transistors (TR1, TR2) of a bistable circuit that is not in the first position in the chain, the output paths further transistors (TR3, TR4) contain their input electrodes with the output electrodes the corresponding transistors (TR1, TR2) of the preceding bistable circuit are coupled, so that these further transistors are non-conductive when the Transistors of the preceding bistable circuit are conductive and vice versa, and that the parallel paths coupled to the input electrodes of the transistors (TR1, TR2) of the first bistable circuit of the chain, the output current paths of further transistors (TR3, TR4) contain their input electrodes with the output electrodes of the opposite Transistors (TR2, TR1) of the last bistable circuit of the chain are coupled, so that these further transistors are non-conductive when the transistors of the last bistable circuit are conductive, and vice versa. Considered publications: German Patent No. 906 705; German document no.T 9226 VIIIa, 21 a '(published 9 B. 1956); Electronics, March 1956, pp. 174-178.